A heat sink clip (1) includes a main body (50), an operating part (30) movably received in the main body, and a pressing cam (70) pivotably attached to the main body. The main body includes a central portion (52), and two hooks (54) depending from opposite ends of the central portion. The operating part includes a driving portion (34) and a handle (32). A plurality of first teeth (346) is formed in the driving portion. The pressing cam includes a plurality of second teeth (74) that mesh with the first teeth. When the handle is slid, the first teeth drive the second teeth to rotate. The pressing cam accordingly rotates until it is forced against a top surface (3a) of a heat sink (3). The main body is thus resiliently displaced upwardly, causing the hooks to be firmly engaged with a socket (5) on which the CPU is mounted.
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1. A clip for attaching a heat sink to heat-generating device, the clip comprising:
a main body having a central portion and two hooks depending away from opposite ends of the central portion, the central portion defining a channel; an operating part movably received in the channel of the main body, the operating part comprising a driving portion and a handle connecting with the driving portion, the driving portion having a plurality of first teeth; and
a pressing cam pivotably attached to the main body and adapted to abut the heat sink, the pressing cam having a plurality of second teeth meshing with the first teeth of the operating part.
15. An electronic device assembly comprising:
a socket;
an electronic device mounted on the socket;
a heat sink attached on the electronic device; and
a clip securing the heat sink to the electronic device, the clip comprising a main body engaged with the socket, an operating part movably received in the main body, and a pressing cam pivotably connected with the main body, the operating part having a driving portion and a handle connecting with the driving portion, the driving portion having a plurality of first teeth, the pressing cam having a plurality of second teeth meshing with the first teeth; wherein
the operating part is actuatable to rotate the pressing cam to press the heat sink.
19. An electronic device assembly comprising:
a socket module with a heat generating device thereon;
at least one catch disposed on a periphery of said socket module;
a heat sink seated upon the heat generating device;
a clip positioning on the heat sink, said clip including:
a central portion with at least one hook extending downwardly from one end thereof;
an operation part and a pressing cam discrete from each other and respectively moveably attached on the central portion, said pressing cam being moved associatively with said operation part, and at least one of said operation part and said pressing cam being pivotal with regard to the central portion; wherein
said operation part and said pressing cam are in a first position where the central portion is in a lower position and the hook and the catch are engaged with each other in a loose manner, while said operation part and said pressing cam are in a second position where the central portion is in an upper position and the hook and the catch are engaged with each other in a tight manner;
wherein said operation part and the pressing cam are configured with gear teeth interengaged with each other for associative movement therebetween.
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1. Field of the Invention
The present invention relates to clips for heat sinks, and more particularly to a clip for a heat sink which facilitates attachment of the heat sink to a heat-generating device such as a central processing unit (CPU).
2. Description of Related Art
Computer central processing units (CPUs) are the core administrators of electrical signals in contemporary computers. Continued development of CPUs has enabled them to perform more and more functions. Correspondingly, heat generated by CPUs is constantly increasing. This can adversely affect the operational stability of computers. To speedily remove heat from the CPUs, heat sinks having great heat conductivity are attached to the CPUs. The heat sinks are commonly attached to the CPUs by clips.
A conventional clip attaches a heat sink to a CPU using screws and springs. However, fastening or removal of the screws using a tool is unduly laborious and time-consuming. Furthermore, there is a risk of accidental damage to the heat sink and its associated printed circuit board (PCB). Moreover, an excessively large tolerance is often accumulated in the CPU/clip/heat sink assembly, which makes the installation less precise and less reliable.
Thus, a clip which overcomes the above-mentioned problems is strongly desired.
Accordingly, an object of the present invention is to provide a heat sink clip which readily and securely attaches a heat sink to a heat-generating electronic device, and which readily detaches the heat sink from the heat-generating electronic device.
In order to achieve the above-mentioned object, a heat sink clip in accordance with a preferred embodiment of the present invention is used to secure a heat sink to a heat generating device such as a CPU. The heat sink clip comprises a main body, an operating part movably received in the main body, and a pressing cam pivotably attached to the main body. The main body comprises a horizontal central portion, and two hooks depending from opposite ends of the central portion respectively. The operating part comprises a driving portion, and a handle extending perpendicularly upwardly from a middle of the driving portion. A plurality of contiguous first teeth is formed in a bottom of the driving portion. The pressing cam comprises a plurality of contiguous peripheral second teeth that mesh with the first teeth of the operating part. When the handle of the operating part is slid along the main body, the first teeth drive the second teeth of the pressing cam to rotate. The pressing cam accordingly rotates until it is forced against a top surface of the heat sink. The main body is thus resiliently displaced upwardly, causing the hooks to be firmly engaged with a socket on which the CPU is mounted. Thus, the heat sink is securely attached on the CPU.
Other objects, advantages and novel features of the present invention will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings.
Reference will now be made to the drawing figures to describe the present invention in detail.
Referring to
The operating part 30 is generally T-shaped. The operating part 30 comprises a driving portion 34, and a handle 32 extending perpendicularly upwardly from a middle of the driving portion 34. A plurality of first teeth 346 is formed in a bottom of the driving portion 34. A longitudinal slanted surface 342 is formed in a middle portion of each of opposite longitudinal sides of the driving portion 34.
The main body 50 comprises a horizontal central portion 52, and two hooks 54 depending from opposite ends of the central portion 52 respectively. The central portion 52 comprises a pair of side walls 564. A channel 56 is defined between the side walls 564, for receiving the operating part 30. A pair of aligned pivot holes 58 is defined in the side walls 564 respectively, for receiving the pin 12. Two stopping boards 562 are formed between the side walls 564 at opposite ends of the channel respectively, for restricting movement of the operating part 30. A longitudinal slanted wall 566 is formed in an inner portion of each side wall 564, for slidably cooperating with the corresponding slanted surface 342 of the operating part 30. A distance between the two stopping boards 562 allows the driving portion 34 of the operating part 30 to slide therebetween.
The pressing cam 70 comprises a plurality of contiguous peripheral second teeth 74, for meshing with the first teeth 346 of the operating part 30. A through hole 72 is defined through a central axis of the pressing cam 70, corresponding to the pivot holes 58 of the main body 50.
In assembly, the operating part 30 is inserted into the channel 56 of the main body 50. The slanted surfaces 342 of the operating part 30 slidably abut the slanted walls 566 of the main body 50. The pressing cam 70 is inserted into the main body 50, with the through hole 72 of the pressing cam 70 aligning with the pivot holes 58 of the main body 50. The pin 12 is pivotably received in the pivot holes 58 and the through hole 72, thus pivotably connecting the main body 50 and the pressing cam 70. The second teeth 74 of the pressing cam 70 are meshed with the first teeth 346 of the main body 30.
Referring particularly to
Referring particularly to
The operating part 40 comprises a driving portion 44, and a handle 42 extending perpendicularly upwardly from the driving portion 44. A plurality of contiguous first teeth 442 is formed around a periphery of the driving portion 44, equidistant from a central axis thereof. A first through hole 444 is defined through the central axis of the driving portion 44.
The main body 60 is similar to the main body 50 of the clip 1. The main body 60 comprises a horizontal central portion 62, and two hooks 64 depending from opposite ends of the central portion 62 respectively. The central portion 62 comprises a pair of side walls (not labeled). A channel 66 is defined between the side walls, for movably receiving the operating part 40 therein. An upper pair of pivot holes 68 is defined in the side walls respectively, and a lower pair of pivot holes 68 is defined in the side walls respectively. A stopping post 69 is formed in a middle portion of the channel 66. The stopping post 69 is used to restrict rotation of the operating part 40. One of the pins 22 is received in the upper pair of pivot holes 68 and the first through hole 444 of the operating part 40, thus pivotably connecting the main body 60 and the operating part 40.
The pressing cam 80 is for pressing the top surface 3a of the heat sink 3 (see FIG. 2). The pressing cam 80 comprises a plurality of contiguous peripheral second teeth 84 equidistant from a central axis thereof, and a second through hole 82 defined through the central axis. The second teeth 84 mesh with the first teeth 442 of the operating part 40. The other of the pins 22 is received in the lower pair of pivot holes 68 of the main body 60 and the second through hole 82, thus pivotably connecting the main body 60 and the pressing cam 80.
In use, the handle 42 is rotated from a vertical position down toward the main body 50, and the first teeth 442 drive the second teeth 84 to rotate. A pressing point of the pressing cam 80 accordingly rotates until it is forced against the top surface 3a of the heat sink 3. The main body 60 is thus resiliently displaced upwardly, causing the hooks 64 of the main body 60 to be firmly engaged with the catches 5a of the socket 5. Thus, the heat sink 3 is securely attached on the CPU 6.
It is to be understood, however, that even though numerous characteristics and advantages of the present invention have been set forth in the foregoing description, together with details of the structure and function of the invention, the disclosure is illustrative only, and changes may be made in detail, especially in matters of shape, size, and arrangement of parts within the principles of the invention to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed.
Lee, Hsieh Kun, Chen, Chun-Chi, Liu, Zhigang
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Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Jun 24 2002 | CHEN, CHUN-CHI | HON HAI PRECISION INC CO , LTD | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 013090 | /0018 | |
Jun 24 2002 | LEE, HISEH KUN | HON HAI PRECISION INC CO , LTD | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 013090 | /0018 | |
Jun 24 2002 | LIU, ZHIGANG | HON HAI PRECISION INC CO , LTD | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 013090 | /0018 | |
Jul 05 2002 | Hon Hai Precision Ind. Co., Ltd. | (assignment on the face of the patent) | / |
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